ArticleName |
Phosphate solution wetting of graphite blocks for magnesium electrolysis to enhance their oxidation resistance. Part 1 |
ArticleAuthorData |
Saint Petersburg Mining University, Saint Petersburg, Russia:
R. Yu. Feshchenko, Associate Professor at the Metallurgy Department, Candidate of Technical Sciences, e-mail: Feschenko_RYu@pers.spmi.ru R. N. Eremin, Postgraduate Student O. O. Erokhina, Postgraduate Student V. M. Dydin, Postgraduate Student |
Abstract |
Graphitized electrodes are broadly used in industry. However, when they are used in high-temperature operating environments, they are subject to oxidation, which can lead to abnormal operation or premature failure of an electrolytic cell. Use of protective coatings or special wetting solutions (melts) help increase the oxidation resistance of a wide assortment of components. It is obvious that a coating that covers an electrode completely will hinder or stop the electric current from flowing at the electrode/electrolyte boundary, which makes this technique inapplicable to anodes for magnesium electrolysis. Aqueous solutions of phosphates are widely used around the world to make materials more resistant to high-temperature oxidation due to the formation of glassy phases during drying. This paper examines the efficiency of using a mixture of zinc and aluminium dihydrophosphates dissolved in an aqueous solution of orthophosphoric acid to enhance the oxidation resistance of the graphite electrode EGP (NR). A comprehensive thermal analysis was carried out to examine the solution for suitability. And X-ray diffractometry helped verify the formation of crystals after the solution had been dried. Cube-shaped specimens with the side length of 50 mm were used in the experiments aimed at identifying optimum graphite wetting and drying conditions. Isopropanol was used as a surfactant to ensure proper wetting. The specimens were first subjected to vacuum degassing for air to be removed from the pores, and then they were soaked in a rarefied solution. A kinetic model was selected to describe the post-wetting drying procedure. The oxidation resistance was analyzed in a dynamic air flow. The experiments were carried out at 700 oC as it is the highest possible temperature for magnesium electrolysis. The results of the experiments showed that the above wetting technique, when applied in a laboratory environment, helped achieve a five-fold increase in the oxidation resistance of the model graphite electrodes. The authors looked at the feasibility of scaling the experiments and developing process circuits to produce graphite with high oxidation resistance. |
References |
1. Kolokoltsev S. N. Carbon materials. Properties, processes, applications: Learner’s guide. Dolgoprudny : Intellekt, 2012. 296 p. 2. Dubovikov O. A., Brichkin V. N. Directions and prospects of using low grade process fuel to produce alumina. Journal of Mining Institute. 2016. Vol. 220. pp. 587–594. DOI: 10.18454/PMI.2016.4.587. 3. Song Y. et al. The impact of cathode material and shape on current density in an aluminum electrolysis cell. JOM. 2016. Vol. 68, No. 2. pp. 593–599. 4. Shchegolev V. I. Electrolytic production of magnesium. Moscow : Ore and Metals, 2002. 366 p. 5. Lokshin M. Z., Makarov G. S. Important problems related to the production and processing of magnesium. Tsvetnye Metally. 2006. No. 5. p. 46. 6. Rubenstein J., Davis B. Wear Testing of Inert Anodes for Magnesium Electrolyzers. Metallurgical and Materials Transactions B. 2007. Vol. 38, No. 2. pp. 193–201. 7. Hao X., Yu Z., Li C., Cao J., Li T., Gou Z. Graphite anode for magnesium electrolysis and preparation method thereof. Patent 102268697 CN. Published: 27.11.2013. 8. Tsaplin A. I., Nechaev V. N. Computational modeling of heat and mass transfer in reactor during magnesium-thermic reduction of titanium. Tsvetnye Metally. 2016. No. 7. pp. 64–70. DOI: 10.17580/tsm.2016.07.08. 9. Lin Y. et al. Fabrication and oxidation resistance behavior of phosphate/borate impregnation for graphite. Surface and Coatings Technology. 2020. Vol. 389. p. 125632. 10. Deng Y. L. et al. Improvement in anti-oxidation of two-step dipping graphite with different solutions. Chinese Journal of Process Engineering. 2012. Vol. 12, No. 1. p. 160. 11. Cheng X. et al. Phosphate adsorption from sewage sludge filtrate using zincaluminum layered double hydroxides. Journal of Hazardous Materials. 2009. Vol. 169, No. 1. pp. 958–964. 12. Hernandez M. et al. Effect of an inhibitive pigment zinc-aluminum-phosphate (ZAP) on the corrosion mechanisms of steel in waterborne coatings. Progress in Organic Coatings. 2006. Vol. 56, No. 2. pp. 199–206. 13. Naderi R., Attar M. M. The role of zinc aluminum phosphate anticorrosive pigment in protective performance and cathodic disbondment of epoxy coating. Corrosion Science. 2010. Vol. 52, No. 4. pp. 1291–1296. 14. Jabri M. et al. Optimisation of hardness and setting time of dental zinc phosphate cementusing a design of experiments. Arabian Journal of Chemistry. 2012. Vol. 5, No. 3. pp. 347–351. 15. Mousavifard S. M. et al. The effects of zinc aluminum phosphate (ZPA) and zinc aluminum polyphosphate (ZAPP) mixtures on corrosion inhibition performance of epoxy/polyamide coating. Journal of Industrial and Engineering Chemistry. 2013. Vol. 19, No. 3. pp. 1031–1039. 16. Pokorný P. Comparison of the thermal stability of magnesium phosphate (newberyite) coating with conventional zinc phosphate (hopeite) coating. Koroze a Ochrana Materialu. 2018. Vol. 62, No. 4. pp. 129–133. 17. Koshelev Yu. I., Bubnenkov I. A. The role of capillary processes in liquid phase siliconizing of carbon materials. Research Institute for Graphite-Based Structural Materials celebrating its 55th anniversary. 2015. pp. 121–153. 18. Butyrin G. M. Density, porous structure, and gas-dynamic characteristics of finely grained graphites (a review). Solid Fuel Chemistry. 2015. Vol. 49, No. 5. pp. 304–318. 19. EPM Group. 2013-2020. Available at: https://www.epmgroup.ru/en/assets/uploads/files/docs/2019/5/epm-booklet-fin.pdf (Accessed: 20.09.2020). 20. Safety regulations applicable to hazardous production sites utilizing pressurized equipment: Approved by Rostekhnadzor on March 25, 2014; Order No. 116. |